Eulerian Multiphase Model, Training Package, Advanced, 10 Practical Exercises
$447.00 Student Discount
This CFD training package is prepared for ADVANCED users of ANSYS Fluent software in the EULERIAN Multi-phase Model area, including 10 practical exercises.
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Description
Eulerian Multi-phase Model CFD Simulation Package, ANSYS Fluent Training for ADVANCED Users
This CFD training package is prepared for ADVANCED users of ANSYS Fluent software in the EULERIAN Multi-phase Model area, including 10 practical exercises. You will learn and obtain comprehensive training on how to simulate projects. The achieved knowledge will enable you to choose the most appropriate modeling approaches and methods for applications and CFD simulations.
DDPM
While the DPM strategy for CFD solutions proved to be an excellent method to calculate flow particle-flow studies, this approach cannot provide reliable answers for dense particle simulations. Therefore, the DDPM (Dense-Discrete-Phase-Method) is mostly employed in CFD projects. In project number 1, we simulated a simple elbow bend. However, the fast injection would result in a dense accumulation of particles. Therefore, a dense DDPM model is employed.
Project number 2 simulates sand particle sedimentation in a water flow channel. The sedimentation phenomenon is one of the destructive phenomena in the quality of performance of any equipment. The Eulerian-Lagrangian perspective on computational fluid dynamics (CFD) is used in the present simulation. The Eulerian multiphase model is coupled with the dense discrete phase model (DDPM). A continuous phase is defined, related to water flow, and a discrete phase is described, which is related to sand particles.
Porous
Project number 3 simulates multi-phase flow in a porous medium. Water flow with a relative pressure of 100,000 pascals and a temperature of 288.15 K enters from the top of a vertical column. It enters a porous media at the end of the column. In the present simulation, a multi-phase model is used; So that its primary phase is liquid water and its second phase is water-soluble particles (sludge).
Non-Newtonian Flow (EULERIAN Multi-phase Model)
Project number 4 simulates a non-Newton two-phase flow between two concentric cylinders. Fluids are divided into two categories in terms of viscosity: Newtonian and non-Newtonian fluids. In this simulation, a two-phase flow is defined using the Eulerian model, the base fluid of which is a non-Newtonian fluid with a soluble fluid flowing through it.
Drone Sprayer
In project number 5, Ansys Fluent software has been used to simulate the agricultural drone sprayer. The system consists of two different fluids, including air as the primary fluid, and one secondary fluid is poison with a density of 0.9512. the Eulerian multiphase model has been used. The toxin is entering the domain with a speed of 5m/s with gravity considered as -9.81 m/s-2 on the y-axis and airspeed is 15 m/s.
Boiling
Project number 6 simulates the boiling process inside a nanotube. A nanotube is a tube that is made at the nano-scale by nano-particles. This simulation assumes that the water SATURATION temperature is 383.15 K; at this temperature, a phase change from liquid water to water vapor occurs. The water stream enters the pipe at a speed of 1e-5 and a temperature of 373.15 K, and since this water stream is close to the saturation temperature, it can be said that it is ready for the boiling process.
Packed Bed Reactor (EULERIAN Multi-phase Model)
In project number 7, a packed bed reactor is simulated. Reactor models vary from pseudo-homogeneous to heterogeneous, from one-dimensional to three-dimensional, and from assumed flow patterns to computed flow and transport fields. Packed bed reactors, also known as fixed-bed reactors, are often used for catalytic processes. A packed bed reactor (PBR) is preferred for heterogeneous reactions, where the solid-fluid contact dramatically influences the reaction rate.
Reverse Osmosis
In project number 8, we simulated reverse osmosis. This mechanism is used to purify water so that a membrane is placed in front of the water movement and does not allow the salts in the water to leave and pure water leaves. The Eulerian Multi-phase model has been used in this project. Inlet water velocity is 0.01 m/s, the volume fraction of solutes is 0.02, And the membrane layer is simulated as a porous medium.
Icing airfoil
Project number 9 simulates the airflow around the airfoil and creates a water film on the surface of the airfoil body. When moisturized air and water droplets hit the airfoil’s surface, a water film may form on the airfoil surface. This work investigates the thickness of the produced and flowing fluid layer on the airfoil body; The Eulerian wall film model was used to simulate and estimate the amount of liquid film produced. This model estimates the formation or flow of a thin film of liquid on the wall surfaces.
Separator (EULERIAN Multi-phase Model)
Project number 10 simulates well drilling and sludge separation. In this simulation, a cylindrical hole is considered a well, inside which a rotating body in the shape of a cylinder is placed. Inside the cavity, a Non-Newtonian material for drilling operations flows; So that the mud particles inside it are mixed. The fluid CMC as the primary phase has a density of 1271.477 kg.m-3, and its viscosity is defined as non-Newtonian, which is according to the Herschel-Bulkley rule; While the soluble particles of mud in the Non-Newtonian fluid also have a density equal to 2000 kg.m-3 and a viscosity equal to 0.00111 kg.m-1.s-1.
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Kylie Smith –
Great resource compiling comprehensive information on Eulerian multiphase models!
MR CFD Support –
Thank you for your positive feedback! We’re delighted to hear our training package for advanced ANSYS Fluent users has proven to be thorough and informative. It’s fantastic to know it provided you comprehensive insights into applying the Eulerian multiphase model to a variety of complex simulations. Should you need further assistance or more advanced resources, don’t hesitate to reach out!
Dock Prosacco –
I finished the Eulerian Multiphase Model training package, and it was truly an enriching learning experience. The simulations were realistic and the step-by-step guidance helped me understand the complexity of multiphase flows. Thank you for such a comprehensive training program.
MR CFD Support –
We are thrilled to receive your positive feedback! It’s great to hear that our Eulerian Multiphase Model training package met your expectations and contributed to your understanding of multiphase flow simulations. If you ever have more questions or need further assistance, feel free to reach out. Thank you for choosing our training program, and we wish you the best in your future endeavors with CFD!
Kyle Simonis –
The range of applications in these exercises seems vast, from drone sprayers to reverse osmosis system simulations. Are the principles learned in this package applicable to industries beyond those specifically addressed in the exercises, for example, pharmaceutical or automotive industry applications?
MR CFD Support –
Yes, the principles taught in this advanced Eulerian Multiphase Model CFD Simulation Package are applicable across a wide range of industries, including pharmaceutical and automotive. The fundamental understanding of multiphase flows, coupled with ANSYS Fluent techniques, provides valuable insights that can be tailored to different industry-specific applications.
Daron Bayer III –
The training package sounds very detailed and varied. I’m interested in learning more about the Dense Discrete Phase Model—is this different than the standard DPM, and are its advantages covered in the training material?
MR CFD Support –
Yes, the Dense Discrete Phase Model (DDPM) is indeed different from the standard Discrete Phase Model (DPM). The DDPM takes into account the volume fraction of the particles when it is no longer negligible, which is particularly useful for dense particle simulations where particle-particle interactions significantly affect the flow. The training material provides insights into when and why to use DDPM over the standard DPM and will guide you through the practical aspects of its implementation in simulations.
Ms. Aaliyah Ward V –
The range and complexity of the exercises provided truly improved my understanding. The detailed examples enabled me to grasp both basic concepts and more challenging aspects of multiphase flow simulation. Great work by MR CFD!
MR CFD Support –
We are delighted to hear that the training package met your expectations and enhanced your understanding of multiphase flow simulation through ANSYS Fluent. Thank you for choosing our Advanced Eulerian Multiphase Model training package and taking the time to provide this positive review!
Newell Gibson DDS –
How does the Eulerian Multi-phase Model differ in simulating sedimentation in comparison to single-phase flow simulations, particular in project number 2 of the training package?
MR CFD Support –
The Eulerian Multi-phase Model allows for the simultaneous simulation of multiple, interacting phases, unlike single-phase flow simulations which can only account for one fluid at a time. In project number 2, the model facilitates the interaction between water flow and sand particles, providing accurate insights into sedimentation behavior that could not be obtained through single-phase flow simulations.
Mr. Bill Kulas –
I just completed the Eulerian Multiphase Model training package and wow – I was blown away by the depth and variety of the practical exercises! Handling ten different complex scenarios has vastly improved my understanding of multiphase flows and has boosted my confidence in applying the Eulerian approach in diverse simulations. The way you explain the transition from classical DPM to DDPM in dense particle regimes was particularly enlightening. Every case study was a stepping stone that built up my knowledge: from the simple elbow bend right up to the compelling separator project. It’s evident a lot of thought was put into creating these exercises!
MR CFD Support –
Thank you so much for such a glowing review! It’s gratifying to hear that our Eulerian Multiphase Model training package has significantly contributed to your learning experience. We strive to impart a thorough understanding of complex CFD concepts, and it’s fantastic to know that our practical approach has enriched your multiphase flow simulation capabilities. Your enthusiasm for the detailed explanations and varied scenarios boosts our motivation to create even more insightful and diverse training resources. Thanks again for choosing our training package, and if you ever need further support, we’re always here to help!
Casper Reichel PhD –
The studies included in this advanced training package are impressive. The range of applications for the Eulerian multi-phase model is thoroughly demonstrated across varying types of fluids, flow conditions, and physical phenomena. I especially appreciate how each project deals with scenarios that present different challenges, enabling deeply experiential learning that prepares learners well for complex CFD simulations. Notably, the inclusion of non-Newtonian flows, multiphase flow in porous media, and complex flow separation processes illustrate the versatility and sophistication of the Eulerian modeling approach. Expertly curated, this knowledge is indispensable for those aiming to elevate their skills in CFD analysis. This training package undoubtedly bridges crucial gaps between academic theory and real-world engineering challenges.
MR CFD Support –
Thank you for your enthusiastic review of our Eulerian Multiphase Model Training Package. We’re pleased to hear that you found the breadth of applications and the depth of challenging scenarios valuable for advanced learning in CFD simulations using ANSYS Fluent. It is great to know that the package’s content met your expectations and enhanced your understanding of complex fluid dynamics. We appreciate the time you took to provide this detailed feedback which acknowledges the quality and educational value of our product. Your comments serve as a testament to our commitment to equipping professionals in the field with top-tier CFD skills.
Rahsaan O’Hara –
This training package appears to be quite rich and diverse regarding multiphase simulations. I am impressed by the practical exercises included, especially the drone sprayer and the boiling nanotube simulation. The real-world applications of these exercises are very relevant to the challenges engineers face today. Thank you for putting together such a comprehensive learning tool.
MR CFD Support –
Thank you for your positive feedback! We are glad to hear that our training package has met your needs and has provided you with relevant and practical simulations that can be applied to real-world engineering challenges. It is our goal to offer a comprehensive learning experience that enriches the user’s understanding of the Eulerian Multiphase Model in ANSYS Fluent. If you need any further assistance or advanced tutorials, feel free to reach out. We are here to support your learning journey!
Norval Watsica –
This training package appears to be comprehensive. I’m particularly interested in project number 3; can you tell me more about how the multiphase flow in a porous medium is approached in ANSYS Fluent?
MR CFD Support –
In ANSYS Fluent, multiphase flow in porous media, like the one in project number 3, is usually approached using a combination of the Eulerian Multiphase model and the porous media model. The fluid flow (liquid water in this case) through the porous medium is simulated considering the interaction between the multiple phases (water and water-soluble particles) and the porous matrix. The fluid passes through the interstices in the porous medium, and its resistance to flow is accounted for by adding a source term in the momentum equations. This simulates the reduced permeability and porosity of the medium. Both phases are treated as interpenetrating continua, and additional constitutive relations are defined to account for the interactions between the phases, as well as the interaction with the porous structure, in addition to specifying boundary and initial conditions suitable for the problem.
Prof. Jamaal Konopelski Sr. –
I just completed the ‘Eulerian Multiphase Model’ training package, and I was impressed by the depth and variety of the practical exercises. In particular, Project number 8 on reverse osmosis was exceptionally detailed and provided me with a better understanding of the process and how to simulate it effectively using ANSYS Fluent. It’s fantastic how the package gradually builds from basic principles to advanced applications!
MR CFD Support –
Thank you so much for your kind words! We’re delighted to hear that our training package has enhanced your understanding of the Eulerian multiphase model, especially the simulation of reverse osmosis. We appreciate the time you spent to share your positive experience, and we take great pride in delivering detailed and educational content. If you have any questions or need further assistance in your learning journey, please don’t hesitate to reach out. Keep up the great work on your CFD simulations!
Dorcas Jaskolski Jr. –
I’ve recently gone through the Eulerian Multiphase Model training package and found myself truly impressed with how well-crafted and educational the exercises were. Each project guided me through successful simulations, enhancing my understanding of advanced CFD techniques. The variety and complexity of problems, from simulating reverse osmosis to the dynamics of a packed bed reactor, offered hands-on experience that was incredibly valuable. This particularly advanced my grasp on employing the DDPM in dense particle flow context, which is often challenging to achieve in simulation. I’m genuinely grateful for such well-structured and insightful material – a huge leap in my computational fluid dynamics journey!
MR CFD Support –
Thank you for your positive feedback! We’re delighted to hear that our Advanced Eulerian Multiphase Model training package has significantly contributed to your understanding of CFD techniques and approaches. The MR CFD Company always strives to provide packages that not only teach but also challenge and enrich the CFD community. Your recognition of the educative value of our exercises strengthens our commitment to excellence in training. If you encounter any curious cases in your future simulations, remember that our expert team is here to support you. Keep up the superb work in your computational fluid dynamics studies and continue growing with our advanced training materials!